Post on 31-Dec-2020
CANADIAN BRISTOL AEROJETW I N N I P E G CANADA
PROPRIETARY INFORMATION
This report includes information which is the property of CanadianBristol-Aerojet Limited, Winnipeg and also information which was sup-plied by, and remains the property of, the Canadian Department ofNational Defence/Defence Research Board and shall not be used orduplicated without the written approval of the appropriate agency.
REVISION 1 , JUNE. 1962
For experiments at greater altitudes, the Black Brant IV-A is currently beingdeveloped. This is a two stage rocket with the Black Brant I motor boosting a BlackBrant III vehicle to an altitude of 600 miles with a 40 pound payload.
A further development of the 17" Black Brant II will be known as the Black BrantV. It is expected to have an altitude capability of 240 miles with 150 pounds ofpayload.
A complete range of telemetry is being developed for this family of rocketstogether with appropriate launchers and other ground handling equipment.
Figure 1.1 illustrates the various ranges of altitude of the Black Brant HighAltitude Rockets together with the positions of some of the interesting areas ofspace, and experiments that can be achieved, with this series.
NOTE:
Propellant temperature range of —20°F to +120°F is listed in this brochurefor the various Black 'Brant vehicles as being the Canadian Bristol Aerojet designobjective.
At present the solid propellant used in all of the Black Brant vehicles is clearedfor storage and use from +30°F to +100°F. An evaluation program is currentlyunderway to clear the propellant for storage and use from 10°F to +125°P andCanadian Bristol Aerojet intend to verify performance down to —20°F.
REVISION 2. NOVEMBER, 1962
TABLE OF CONTENTS
Section 1
Section 2
Section 3
Section 4
Section 5
Section 6
Section 7
Section 8
Section 9
Section 10
INTRODUCTION
GENERAL DESIGN PHILOSOPHY
BLACK BRANT II
BLACK BRANT III
BLACK BRANT IV-A
BLACK BRANT V
INSTRUMENTATION
LAUNCHER EQUIPMENT
REVIEW OF THE CAPABILITIESOF BLACK BRANT FAMILY
CONVERSION FACTORS —WEIGHTS AND MEASURES
Section 1
INTRODUCTION
1 INTRODUCTION
The Black Brant Series of High Altitude Research Rockets is being developedspecifically for the varied requirements of scientific and defence space research asa joint Canadian Government-Canadian Industry Program. This series of utility ve-hicles will initially cover an altitude range of between 100 miles and 600 miles withpayloads of from 25 pounds to 300 pounds. Launching can be carried out over awide temperature range and simple launching facilities are required.
The team developing these vehicles is made up of the Canadian Departmentof Defence Production (DDP), The Defence Research Board (DRB). and CanadianBristol-Aerojet Limited (CBA). The Canadian National Research Council (NRC), isalso assisting in the design and development phases of the program. User agenciesare monitoring the program and providing information to ensure the developmentof a product most suited to the requirements of all users. The solid propellant motordevelopment including development of propellant, internal insulants, igniter andnozzle is being carried out by the Canadian Armament Research and DevelopmentEstablishment (CARDE) of DRB. Process design, propellant filling and static testingis conducted by CARDE. Dynamic testing is conducted jointly by CBA and CARDE.
The family of rockets known as the Black Brant series consists of a single stage17" diameter rocket, one of 10" diameter, and a 2 stage vehicle which utilizes the10" diameter rocket with a 17" diameter booster. The altitude range covered bythese is the region above the limit of balloons and into the zone of satellites.
The initial Black Brant vehicle was designed to a CARDE specification in 1956to enable evaluation of the solid propellant motor to be carried out under dynamicconditions. The success of the dynamic test vehicle, known as the Black Brant I, ledto its acceptance in Canada as a high altitude research rocket. A high degree ofreliability has been experienced with the Black Brant I motor.
The performance potential of the Black Brant I motor led to the developmentof a high altitude research vehicle with improved structural design, nose cone, andfins. This vehicle is known as the Black Brant II. The basic Black Brant II, referredto as the Black Brant 11-A, will carry a 150 pound payload to an altitude of 125miles.
Black Brant III, a 10" diameter rocket, provides a more economical approachto High Altitude Research. The design performance is an altitude of 120 mileswith a 40 pound payload.
REVISION 1 , JUNE. 19&2
For experiments at greater altitudes, the Black Brant IV-A is currently beingdeveloped. This is a two stage rocket with the Black Brant I motor boosting a BlackBrant III vehicle to an altitude of 600 miles with a 40 pound payload.
A further development of the 17" Black Brant II will be known as the Black BrantV. It is expected to have an altitude capability of 240 miles with 150 pounds ofpayload.
A complete range of telemetry is being developed for this family of rocketstogether with appropriate launchers and other ground handling equipment.
Figure 1 .1 illustrates the various ranges of altitude of the Black Brant HighAltitude Rockets together with the positions of some of the interesting areas ofspace, and experiments that can be achieved, with this series.
KILOS. MILESISOOl
Section 2
GENERAL
DESIGN PHILOSOPHY
2 GENERAL DESIGN PHILOSOPHY
A wide choice of motor sizes, methods of launching, attitude control, and coup-ling. etc. is available to the rocket designer. Any of the many combinations of these,results in a vehicle differing from the others in cost, complexity of construction, per-formance, reliability, etc.
The basic vehicle characteristics that were chosen to govern the design of theBlack Brant Rockets are the following, not necessarily in order of preference:
(1) Performance
(2) Availability and Utility
(3) Reliability
(4) Cost Effectiveness
(5) Simplicity of Design and Launch Procedure
(6) Launch Capability Over a Wide Range of Environmental Conditions.
2.1 PERFORMANCE
Although there is a general requirement to cover the altitude zone from 30kilometers (100,000 ft.) to 1500 kilometers (5,000.000 ft.), the main interest appearsto be in the region up to about 1.000 kilometers (3,300,000 ft.) The initial designaim therefore, was to produce a family of vehicles to carry 40 pounds of payloadup to 1,000 kilometers in altitude.
2.2 AVAILABILITY AND UTILITY
The success of the CARDE propellant test vehicle suggested that this generaldesign concept and the CARDE solid propellant should be the basis for the BlackBrant family of research rockets.
The 10" rocket was conceived for use as a single stage vehicle for requirementsup to 650,000 feet. and as the second stage of the high altitude vehicle.
Both basic rockets, therefore, have been designed for use either singly or withthe minimum of modification as components of multi-stage vehicles. This increasedthe utility and usefulness of both.
2.3 RELIABILITY
A high order of reliability is achieved by the combination of a proven motorand simplicity of design in staging and separation.
2.4 COST EFFECTIVENESS
The purpose of the design was to produce the maximum performance with aminimum of cost.
2.5 SIMPLICITY OF DESIGN
Although improved performance is possible by the use of some form of auto"mafic flight control system, it was considered that this would add to the complexityand cost. Since the requirement can be met without the use of this control, it wasnot included in the design approach.
2.6 LAUNCH CAPABILITY OVER A WIDE RANGE OFENVIRONMENTAL CONDITIONS
Simplicity of launching, coupled with the proven performance of the CARDEsolid propellant engine over a wide range of environmental conditions, insures re-liability and ease of launching.
Section 3
BLACK BRANT II
3 BLACK BRANT II
3.1 GENERAL
Although this vehicle was developed from the Black Brant I under the overalldesign authority of CARDE. the marketing responsibility for the Black Brant II restswith CBA. It is a solid propellant, three finned, unguided sounding rocket designedfor zero roll rate. The original Black Brant II vehicle is identified as the Black Brant11-A. When equipped with a more recently developed CARDE solid propellant en-gine, the vehicle will be known as the Black Brant 11-B.
3.2 BLACK BRANT II.A DETAILS
3.2.1 CONFIGURATION
The basic configuration as detailed in Figure 3-1 consists of:
(1) Nose — conical followed by cylindrical section.
(2) Motor — solid fuel, fixed nozzle.
(3) Stabilizers — fixed fin.
3.2.2 NOSE
The 86.0" long conical portion is followed by a 24.6" long cylindrical sec-tion. Approximately 6 cubic feet of volume is available for a maximum payloadweight of 300 pounds.
3.2.3 ROCKET MOTOR
The Black Brant II-A motor section is comprised of a solid propellant15KS25000 rocket motor.
3.2.4 STABILIZERS
Three fixed fins are used. Each fin has a leading edge sweepback of approxi-mately 55°, a trailing edge sweepback of 30°, with a semi-span of 30.4" and a rootchord of 51.5". Total individual fin area is 1050 square inches.
3.2.5 COMPLETE VEHICLE
The complete vehicle has an outside diameter of 17.2" and an overall lengthof 332.5".
REVISION I.JUNE. 1962
3.2.6 WEIGHTS
Weight of Loaded Rocket Motor. Inc. nozzle, poundsnozzle, pounds ......... ..
kilograms .... .. ....
pounds ...
kilograms . .
1LE)
753417
986.550
2.00062.000
735,000
139224
260.000
—20 to 120—29 to 49
seconds ....pounds .. ...... .kilograms .. .. .pounds .. . ...
15068
16
956.0701,840
660,000
125
201205
-,....... ..............
2.264
....... ......1.027
..... .. . 2.550............1.156
300136
14
905.200
1.580
455.000
86
138
(Objective)(Objective)
..... . 15.5... ... ... 18.8.. ......... 24.700............ 1 1 . 1 7 4. . ..383,200
kilograms
Total Rocket Weight (less payload). pounds ... ..kilograms . ..
3.2.7 PERFORMANCE (85° LAUNCH ANGLE)
Payload, poundsPayload, kilograms
Maximum Acceleration "G"Launch velocity with 15 foot launcher,
ft./sec.
Maximum velocity, ft./sec., meters/sec.
Altitude at burnout, feetPeak Altitude, feet
, miles, kilometers
Time to peak altitude, seconds
Range, feetPropellant Temp. Range, °F
. °C
3.2.8 BALLISTIC DATA (70° F. AMBIENT)
Square Wave Burning Time. secondsActual Burning Time (to zero thrust), secondsSquare Wave Thrust (sea level), pounds .. ..
kilograms ..
Total Impulse (sea level), pounds - seconds .. .
3.3 BLACK BRANT II-B DESIGN DETAILS3.3.1 GENERAL
The Black Brant II-B will be identical in configuration and dimensions to theBlack Brant II-A except for propellant configuration and nozzle.
REVISION I, JUNE. 1962
3.3.2 ROCKET MOTOR
The motor section will be composed of a solid propellent 23KS20000 rocketmotor with a nozzle exit diameter of 14".
3.3.3 WEIGHTS
Weight of Loaded Rocket Motor, pounds ..., kilograms
pounds ... ..........kilograms -. . ...
pounds ..........kilograms.
GLE)
7534
14.5
'
7.470
2.280
1.056,000
200322
. .... ............ ..... 2.537
..................... ... . 1 .151
............................ -...2.817
. ............. ............1.300
150 30068 13613.5 11.7
797.077 6.3702.160 1.820
97.200•
950.400 765.600
180 145290 133
258
Total Rocket Weight (less payload), pounds, kilograms
3.3.4 PERFORMANCE (85° LAUNCH ANGLE)
Payload, poundsPayload, kilogramsMaximum acceleration "G"
Launch velocity with 15 foot launcher,ft/sec.
Maximum velocity, ft./sec., meters/sec.
Altitude at burnout, feet
Peak Altitude, feet
, miles., kilometers
Time to Peak Altitude, secondsRange, feetPropellent Temp. Range. °F -20 to 120 (Objective)
-29 to 49 (Objective). °c
3.3.5 BALLISTIC DATA (70°F)
Square Wave Burning Time, seconds .... ...... .Actual Burning Time (to zero thrust), secondsSquare Wave Thrust (sea level), pounds ..... .. .
, kilograms . . ..
Total Impulse (sea level), pounds - seconds ..
. . 23.528.5
19.2008,609
.452.000
REVISION I.JUNE. 19&2
BLACK BRANT II ROCKET
View OnArrow "A"
Figure 3 - 1
TYPICAL OGIVE NOSE CONE
BLACK BRANT II
(17" forward body shown)
.DETACHABLE NOSE TIP
Figure 3-2
Section 4
BLACK BRANT III
4 BLACK BRANT III
4.1 GENERAL
The Black Brant III is a three finned, unguided sounding rocket, utilizing solidrocket propellent and designed for zero roll rate. It is basically a single stage ve-hicle, however, the 10" motor can also be used as a stage for multi-stage rockets.
4.2 REQUIREMENT
Typical potential uses are: cosmic ray and auroral investigations, — meteor-ological observations above balloon altitudes, — as a basis for a communication de-vice.
4.3 DESIGN DETAILS
4.3.1 CONFIGURATION
The basic configuration as detailed in Figure 4-1, consists of:
(1) NOSE — conical followed by a cylindrical section.
(2) MOTOR — This will be identical for all roles except for nozzleswhich will be optimized for each of the operations.
(3) STABILIZERS — These will take two forms; one for single stage,and another for multi-stage operation.
The static margin provided by the stabilizers are as follows:
(1) Two-Stage Operation — At M = 1 3 with 40 Ib. payload — 2calibres.
(21 Single Stage Operation — At M = 7.0 with 40 Ib. payload — 1calibre.
4.3.2 NOSE
With a 49.3" cone section and a 16.9" cylindrical section, approximately1.4 cubic feet of space is available for instrumentation. It has been found thatthis configuration is suitable for all roles. However, this may be changed somewhatto meet individual requirements.
4.3.3 ROCKET MOTOR
The basis of this motor is a tube of 131.2" in length, 10.2" outside dia-meter and .057" wall thickness.
4.4 WEIGHTS
Weight of loaded Rocket Motor, pounds................................................... 583
, kilograms......... .........................................265
Total Rocket Weight (less payload), pounds.............................................. 621
, kilograms............................................. 282
4.5 PERFORMANCE (85° LAUNCH ANGLE)
Payload, pounds 25
Payload, kilograms 11
Maximum acceleration, "G" 31
Launch velocity with 10.5 foot launcher,ft./sec. 122
Maximum velocity, ft./sec. 7,055
, meters/sec. 2,140
Altitude at burnout, feet 50.100
Peak Altitude, feet 685.000
, miles 130
. kilometers 208
Time to Peak Altitude, seconds 215
Range, feet 145,000
Propellant Temp. Range, °F
. °c
40 7518 3430 27
1 1 9 1 1 5
6.782 6.266
2,060 1,900
48,500 45,300
633.000 528,000
120 100
193 161
212 196
137.000 118.000
-20 to 120 (Objective)
-29 to 49 (Objective)
NOTE:
(1) Single Stage — As a single stage vehicle, the 10" Rocket will carry 40pounds up to approx. 630,000 feet. A 25 pound payload can be carried upto 685.000 feet.
(2) Second Stage — With the same general characteristics when coupledwith the Black Brant I and a second stage commencing burning after firststage burnout (which occurs at approximately 50,000 feet) the 10" Rocketwill carry 40 pounds of payload a further 3.050,000 feet for a totalheight of 3.100.000 feet.
REVISION 1. JUNE. 1962
4.6 BALLISTIC DATA (70° P)
Square Wave Burning Time. seconds .... .. . ........ ....... . ....... .. 9.0
Actual Burning Time (to zero thrust), seconds . . . . . . . . . . . . 1 2 . 1
Square Wave Thrust (sea level), pounds.... . . 10,800
, kilograms 4.899
Total Impulse (sea level), pounds - seconds .. - . . 97,500
EFFECT OF PAYLOAD ON PEAK ALTITUDE
BLACK BRANT III
TOTAL VEHICLE WEIGHT 621 LBS.(Without Payload)
LAUNCH ANGLENO DISPERSION
Figure 4- 2
Figure 4-3
Section 5
BLACK BRANT IV
5 BLACK BRANT IV
5.1 GENERALThis rocket is a two-stage fixed finned vehicle using solid propellant in both
stages. The initial Black Brant IV will be known as the Black Brant IV-A. Future de-velopment of the Black Brant IV-B is planned.
5.2 BLACK BRANT IV-A DETAILSThe vehicle Black Brant IV-A was designed around the Black Brant I motor
and the Black Brant III vehicle.
5.2.1 10" ROCKET — SECOND STAGEBody Diameter 10.2 inches
Body length (without nose cone) 147.3 inches
Body cross-sectional area .565 sq.ft.
Payload compartment length ' 63.3 inches
5.2.2 17" ROCKET — FIRST STAGEBody diameter 17.2 inches
Body length (without nose cone) 184.0 inches
Body cross-sectional area 1.615 sq. ft.
5.2.3 CONFIGURATIONThe configuration as shown" in Figure 5-1, consists of 4 major sections:
SECTION 1 — The 10" Rocket attached and faired to the first stage.
SECTION 2 — Attachment and separation devices.
SECTION 3 — The 17" Black Brant I motor casing.
SECTION 4 — Stabilizing fins for the combined vehicle.
5.2.4 STABILIZING FINSThe fins being developed are of delta shape with a semi-span of 13.0 inches,
a root chord of 44.3 inches and a leading edge sweepback of 71°.
5.2.5 WEIGHTSWeight of loaded rocket motor (Inc. noxile), pounds ....... ....594 & 2,300
, kilograms 275 & 1.040
Total Rocket Weight (minus payload), pounds... . ... 3.104
, kilograms . . 1,410
5.2.6 PERFORMANCE (85° LAUNCH ANGLE)
Payload. pounds 25Payload, kilograms 11Maximum acceleration, "G"
Launch velocity with 1 5 foot launcher,
38
ft./sec.Maximum velocity, ft./sec. 13,46013.460
4.100—
3.400.000
643
1.035—
13.2304.060
113,0003.190,000
604972446
12.7003,870
—2.870.000
543874—
. meters/sec. 4,100Altitude at burnout, feetPeak Altitude, feet
. miles, kilometers
Time to Peak Altitude, secondsRange, feetPropellant Temp. Range, °F
. °C
NOTE:
401836
753433
—20 to 120 (Objective)—29 to 49 (Objective)
The altitude and speed of the two-stage vehicle at the time of first stagemotor burnout with a 40 Ib. payload is of the order of 50.000 feet atMach. 4.9. With the second stage firing with zero delay after the endof burning of the first stage the approximate maximum altitude of theconfiguration is calculated to be 3.100.000 feet with a 40 pound payload.
The time for commencement of burning of the second stage appears tobe optimized in relation to aerodynamic heating, dispersion, loading,maximum altitude and drag if 0 seconds delay is allowed.
5.2.7 BALLISTIC DATA (70° F)
Square Wave Burning Time, seconds ...... .... . . . .Actual Burning Time (to zero thrust), seconds .Nominal Thrust (sea level and 60,000 ft.), pounds .
. kilograms
Total Impulse (sea level and 60.000 ft.).pounds - seconds
1st Stage15.518.8
24.50011 ,100
383.200
2nd Stage9.0
12.t12,6505.750
113.700
REVISION I. JUNE. 19&2
5.2.8 STAGE ATTACHMENT AND SEPARATION
(a) ATTACHMENTThe upper and lower stages are attached by an arrangement which utilizes
•the upper stage nozzle as the structural joint. The aft end of this nozzle registersin a circumferential groove, cut in a heavy ring located at the forward end of ashort parallel body section mounted ahead of the first stage motor. Integral withthis end-ring is a long spigot, which passes up inside the second stage nozzle tolocate against the inside face of the expansion cone.
The upper stage nozzle remains firmly registered in the end-ring due to thedownward inertia force present when the first stage is burning. Any lateral mo-ments are reacted by side thrusts on the forward end of the spigot, and on thesides of the end-ring circumferential slot.
Longitudinal webs are used as stiffeners between the nozzle and the conicalstabilizer.
(b) SEPARATIONThe two stages remain in positive contact only as long as an upward ac-
celeration exists. With burnout of the first stage motor, the greater drag of thebooster creates a differential force to separate the stages. Firing of the second stagemotor then commences.
5.3 BLACK BRANT IV-BUltimately it is Intended to replace the 17" Black Brant I first stage with
the motor being developed for the Black Brant V. The resulting vehicle will be knownas the Black Brant IV.B.
EFFECT OF PAYLOAD ON PEAK ALTITUDE
BLACK BRANT 1VA
0 20 40 60 80 100
PAYLOAD - LBS.
Figure 5-2
Section 6
BLACK BRANT V
6 BLACK BRANT V
6.1 REQUIREMENTTo meet the requirement for carrying heavier payloads to increased altitudes,
Black Brant V is being developed. It will be capable of carrying a payload of 150pounds to an altitude of 240 miles.
6.2 CONFIGURATION
The basic configuration as detailed in Figure 6-1 will consist of:
6.2.1 NOSEThis is a tangent ogive followed by a cylindrical section for single stage role
providing approximately 8 cubic feet of payload volume. The nose will be lighterthan on Black Brant II to improve performance. Various cylindrical lengths will beavailable. The nose is replaced by Black Brant III for the two stage vehicle.
6.2.2 MOTORThe motor, including the nozzle, will be identical for both roles. The use of
higher strength steels will result in a lighter motor than used in Black Brant II.
6.2.3 STABILIZERSThree fins. These will be smaller and lighter than the Black Brant II.
6.3 WEIGHTSWeight of loaded Rocket Motor (Inc. nozzle), pounds . . . . . . 2,459
. kilograms... . . 1 . 1 1 5
Total Rocket Weight (minus payload), pounds..... . 2,639
, kilograms . . . . . . . .1.190
6.4 PERFORMANCE DATA (85° LAUNCH)
Payload, pounds 75 150 300
Payload, kilograms 34 68 136
Maximum acceleration "G" — 18 —
Launch velocity with 1 5 foot launcher.ft./sec. — 82 —
Maximum velocity, ft./sec. 9,130 8,530 7.580
. meters/sec. 2,780 2,600 2.320
Altitude at burnout, feet 120,000 112,000 98,000
6.4 PERFORMANCE DATA (85° LAUNCH) Cont'd.
Peak Altitude, feet 1.430,000 1,267.000 1,000.000
. miles 270 240 190
. kilometers 435 386 305
Time to Peak Altitude, seconds — 308 —
Range, feet — — —
Propellant Temp. Range. °F —20 to 120 (Objective)
. °C —29 to 49 (Objective)
6.5 BALLISTIC DATA (70° F)
Square Wave Burning Time. seconds .. .- ... . . . . . . . . ... 23.5
Actual Burning Time (to zero thrust), seconds . ...... ....... . . . . . 28.5
Nominal Thrust (sea level), pounds . ............. ............................ ...... 19.200
. kilograms . .. ... ... . .. .. .. .. ....... . ... 8.709
Total Impulse (sea level), pounds-seconds ... .... ...... .. ... .....452.000
REVISION I.JUNE, 1962
BLACK BRANT V
17" ROCKET
Figure 6 -1
EFFECT OF PAYLOAD ON PEAK ALTITUDE
BLACK BRANT V
TOTAL VEHICLE WT.(Without Payload)
LAUNCH ANGLENO DISPERSION
Figure 6-2
TYPICAL OGIVE NOSE CONE^——-^——DETACHABLE NOSE TIP
BLACK BRANT V
(22" forward body shown)
Figure 6-4
Section 7
INSTRUMENTATION
7 INTRODUCTION
Bristol has available standard telemetry packages for the Black Brant ve-hicles and is currently developing instruments for measuring rocket performance.
7.1 TELEMETRY PACKAGESTwo basic packages are presently available.
The package for the 17" vehicle provides 10 telemetry channels and that forthe 10" vehicle has 5 channels. The basic 10" package which has been designed forthe Black Brant III is completely transistorized, however, a version using vacuum tubesis also available. All of these packages have one of the channels, "time multiplexed".which is capable of handling up to 25 sources of commutated information.
Design environmental conditions for the basic 17" package include accelera-tion of 26 g. for one minute, shock loading of 25 g. for 10 milliseconds and a de-sign temperature range of from minus 20° to plus 75° Centigrade.
Both versions of the 10" package have been designed for vibrational accel-eration of 1 5 g. at 20 to 2,000 c.p.s. with a maximum acceleration of 60 g., andshock loading of 50 g. for 10 milliseconds. Design temperature range for these pack-ages is also minus 20° to plus 75° Centigrade.
Some additional details are as follows:
7.1.1 17" TELEMETRY PACKAGE
Weight 35 Ibs.
Volume Approximately 700 cu. in.
Transmitter Power Output 5 watts.
Operating Voltage 26.2 volts. D.C. (Silver-zinc batteries)
Effective Range Approximately 300 miles
Frequency 216 to 230 mc.
Band Width 300 kc.
7.1.2 TRANSISTORIZED 10" PACKAGEWeight Approximately 17 Ibs.
Volume Approximately 500 cu. in.
Transmitter Power Output 1 watt.
Operating Voltage 33.4 volts D.C. (Silver-zinc battery)
Effective Range 140 miles
7.1.2 TRANSISTORIZED 10" PACKAGE (Cont'd.)Frequency Capable of 216 to 260 me.Band Width 300 kc.
7.1.3 10" VACUUM TUBE TELEMETRY PACKAGEWeight 30 Ibs.
Transmitter Power Output 5 watts.
Operating Voltage 26.2 volts D.C. (Silver-zinc batteries)
Effective Range Approximately 300 miles
Frequency 216 to 230 me.
Band Width 300 kc.
7.2 QUADRALOOP ANTENNAA new quadraloop telemetry antenna was developed by the Radio and Elec-
trical Engineering Division of the National Research Council primarily for use onthe Black Brant III vehicle where the high temperatures and mechanical forces makethe use of blade antennas impractical.
This quadraloop antenna which weighs less than two pounds has a frontalarea of less than one square inch and is capable of handling a power of 5 watts.
Radiation patterns checked on a model rocket indicate uniform coverage± 2 db, in 60° cones fore and aft with two narrow nulls in the radial direction.
7.3 ALTITUDE SENSING INSTRUMENTThis unit utilizes the Pfotzer cosmic ray maximum layer to provide an inex-
pensive and yet reasonably accurate indication of the altitude achieved by thevehicle. Accuracy of plus or minus 2 to 5 km. is expected.
7.4 ROLL-RATE MAGNETOMETERTo measure the spin-rate and assist in determining vehicle attitude, a roll-
rate magnetometer is used. This instrument utilizes the earth's magnetic field andprovides an inexpensive substitute for a roll-rate gyro system.
7.5 GROUND TEST EQUIPMENTA preflight telemetry check-out console has been developed primarily for use
with the Black Brant III vehicle. With the addition of antenna and recording equip-ment. this console can be used as a complete ground station. Similar equipment isbeing developed for subsequent Black Brant vehicles.
COSMIC RAYALTITUDE
BATTERY
ROLL RATEMAGNETOMETER
TELEMETRY
TELEMETRY
Figure 7-1 PROTOTYPE INSTRUMENTATION FOR BLACK BRANT III10" ROCKET
Section 8
LAUNCHER EQUIPMENT
8 LAUNCHER EQUIPMENT
8.1 LAUNCHING EQUIPMENT GENERAL
8.1.1Launching simplicity has been a major design criterion for the Black Brant
rocket family. The vehicles are designed to enable launching from almost all boomor tower type launchers with only minor modification to the vehicles or launcher.
8.1.2The standard vehicles are designed for use with an underslung three rail
launcher, however, with minor modification the single rail system may also be em-ployed. An optional four-fin kit is included in the design to provide further ver-satility.
8.2 LAUNCHER FOR BLACK BRANT III
8.2.1A 10 foot effective length launcher for use in conjunction with Black Brant
III will be available. The launcher is not a fixed installation, being capable of move-ment from site to site. It is stabilized by four out-riggers, which are bolted at theirextremities to four small foundation points; these are permanently located at thefiring site. The CBA launcher is an underslung type, the rocket carried on railsmounted on the underside of a large diameter tubular boom. This boom can behydraulically elevated to a maximum of 90°. and the whole structure is capableof independent rotation through 360° in azimuth. A sketch showing general arrange-ment of the CBA launcher for Black Brant III is shown in figure 8.1.
8.2.2Trajectory dispersion calculations for the Black Brant III are based on a
launcher of 10 ft. 6 in. effective length, with "zero tip-off". Use of a longer launcherwill reduce dispersion.
REVISION I.JUNE. 1962
BLACK BRANT III LAUNCHER
Figure 8-1
Section 9
REVIEW OF THE CAPABILITIES OF
BLACK BRANT FAMILY
Section 10
CONVERSION FACTORS
1 0 CONVERSION FACTORS — WEIGHTS AND MEASURES
10.1
The following conversion factors will serve as a handy reference to those fac-tors that may be useful for the interpretation of information contained in thebrochure:
Inches
Inches
Centimeters
Feet
Meters
Miles
Kilometers
Pounds
Kilograms
x
x
x
x
x
x
x
x
x
.0835 =
2.54 =
0.3937 =
0.3048 =
3.2808 =
1.6093 =
0.62137 =
0.45359 =
2.2046 =
feet (ft.)
centimeters (cm,
inches (in.)
meters
feet (ft.)
kilometers (km.)
miles
kilograms
pounds
PERFORMANCE DATA
PAYLOADWeight (Useful Payload) . . . . . . . . . . . . . . . 1.0 Co 6 . 8 Kgs.Diameter ( O . D . ) . . . . . . . . . . . . . . . . . . . . . . . 12.38cm.Length . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 7 . 7 6 c m .
LAUNCH DATALauncher . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Boxed RailAzimuth . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Variable 0 to 36CElevation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Adjustable 60° to
TYPICAL VEHICLE FLIGHT DETAILS, 3.2 KGS. USEFUL PAYLOADLaunch Angle, sea level . . . . . . . . . . . . . . . 80°Apogee Altitude (nominal) . . . . . . . . . . . . . 71 Km.Burnout Velocity (approx.) . . . . . . . . . . . . 1450 m/sBurnout Altitude (approx.) . . . . . . . . . . . . 9450 mBurning Time . . . . . . . . . . . . . . . . . . . . . . . . . . 8 . 9 sees.Time to Apogee . . . . . . . . . . . . . . . . . . . . . . . . 120 sees.Range at Apogee . . . . . . . . . . . . . . . . . . . . . . . 26 Km.Nominal Spin Rate at - • ' '
Separation/Apogee . . . . . . . . . . . . . . . . . . . 17 rpsAcceleration . . . . . . . . . . . . . . . . . . . . . . . . . . 45 g (max.)
WEIGHTSLaunch ( 3 . 2 Kgs. Payload with
Parachute) . . . . . . . . . . . . . . . . . . . . . . . . . . 52.4 Kg.Nose Cone (phenolic) and Pedestal . . . . . 4.3 Kg.Separation System & Cannister . . . . . . . . . 0.57 Kg.
ADDITIONAL DATA
Storage Life . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 years
Temperature Limits (storage) . . . . . . . . . . . . -53° C to 67° C(operation) . . . . . . . . . . -45° C to 61° C
Payload SeparationInitiation . . . . . . . . . . . . . . . . . . . . . . . . . . . . G-SwitchDelay . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Mechanical TimerMethod . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Gas Pressure
ParachuteConfiguration . . . . . . . . . . . . . . . . . . . . . . . . . Nylon CircularWeight . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .954 Kg.Descent Rate (average) . . . . . . . . . . . . . . . . 10 m/sec.
Payload HousingPedestal . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Integral with moto
casing. HousesSeparation Systemand Parachute.
Fire Control System Input . . . . . . . . . . . . . . . 115 Volts A . C .
P. 0. BOX 874, WINNIPEG.C A N A D A R3C 2S4TELEPHONE (204) 775-8331TWX 6 1 0 - 6 7 1 - 3 5 9 8TELEX 07-57774 - 07-S7804
bristolaerospace limited
BB 6 APOGEEPERFORMANCE
0 2 4 6 8 10 12 14 16 18 20 22
PAYLOAD WEIGHT - POUNDS
PERFORMANCE DATA
PAYLOADWeight: (Useful Payload) . . . . . . . . . . . . . . . 1 . 0 to 6.8 Kgs.Diameter ( O . D . ) . . . . . . . . . . . . . . . . . . . . . . . 12.38cm.Length . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 87.76 cm.
LAUNCH DATALauncher . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Boxed RailAzimuth . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Variable 0° to 36CElevation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Adjustable 60° to
TYPICAL VEHICLE FLIGHT DETAILS, 3 . 2 KGS. USEFUL PAYLOADLaunch Angle, sea level . . . . . . . . . . . . . . . 80°Apogee Altitude (nominal) . . . . . . . . . . . . . 71 Km.Burnout Velocity (approx.) . . . . . . . . . . . . 1450 m/sBurnout Altitude (approx.) . . . . . . . . . . . . 9450 mBurning Time . . . . . . . . . . . . . . . . . . . . . . . . . . 8 . 9 sees.Time Co Apogee . . . . . . . . . . . . . . . . . . . . . . . . 120 sees.Range at Apogee . . . . . . . . . . . . . . . . . . . . . . . 26 Km.Nominal Spin Rate at
Separation/Apogee . . . . . . . . . . . . . . . . . . . 17 rpsAcceleration . . . . . . . . . . . . . . . . . . . . . . . . . . 45 g (max.)
WEIGHTSLaunch ( 3 . 2 Kgs. Payload with
Parachute) . . . . . . . . . . . . . . . . . . . . . . . . . . 52.4 Kg.Nose Cone (phenolic) and Pedestal . . . . . 4.3 Kg.Separation System & Cannister . . . . . . . . . 0.57 Kg.
ADDITIONAL DATA
Storage Life . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 years
Temperature Limits (storage) . . . . . . . . . . . . -53 C to 67 C(operation) . . . . . . . . . . -45° C to 61° C
Payload SeparationInitiation . . . . . . . . . . . . . . . . . . . . . . . . . . . . G-SwitchDelay . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Mechanical TimerMethod . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Gas Pressure
ParachuteConfiguration . . . . . . . . . . . . . . . . . . . . . . . . . Nylon CircularWeight . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .954 Kg.Descent Rate (average) . . . . . . . . . . . . . . . . 10 m/sec.
Payload HousingPedestal . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Integral with moto
casing. HousesSeparation Systemand Parachute.
Fire Control System Input . . . . . . . . . . . . . . . 115 Volts A . C .
P. 0. BOX 874, W I N N I P E G .bristoIaero space limited C A N A D A R3C 2S4
T E L E P H O N E (204) 775-8331TWX 610-671-3598T E L E X 07-57774 - 07-57804